Channel estimation and spatial processing for tdd mimo systems

ABSTRACT

Channel estimation and spatial processing for a TDD MIMO system. Calibration may be performed to account for differences in the responses of transmit/receive chains at the access point and user terminal. During normal operation, a MIMO pilot is transmitted on a first link and used to derive an estimate of the first link channel response, which is decomposed to obtain a diagonal matrix of singular values and a first unitary matrix containing both left eigenvectors of the first link and right eigenvectors of a second link. A steered reference is transmitted on the second link using the eigenvectors in the first unitary matrix, and is processed to obtain the diagonal matrix and a second unitary matrix containing both left eigenvectors of the second link and right eigenvectors of the first link. Each unitary matrix may be used to perform spatial processing for data transmission/reception via both links.

Claim of Priority under 35 U.S.C. §120

The present Application for Patent is a continuation of patent application Ser. No. 10/693,171 entitled “CHANNEL ESTIMATION AND SPATIAL PROCESSING FOR TDD MIMO SYSTEMS” filed Oct. 23, 2003, allowed, and assigned to the assignee hereof and hereby expressly incorporated by reference herein.

BACKGROUND

1. Field

The present invention relates generally to data communication, and more specifically to techniques to perform channel estimation and spatial processing in time-division duplexed (TDD) multiple-input multiple-output (MIMO) communication systems.

2. Background

A MIMO system employs multiple (N_(T)) transmit antennas and multiple (N_(R)) receive antennas for data transmission. A MIMO channel formed by the N_(T) transmit and N_(R) receive antennas may be decomposed into N_(S) independent channels, with N_(S)≦min{N_(T), NR_(R)}. Each of the N_(S) independent channels is also referred to as a spatial subchannel or an eigenmode of the MIMO channel and corresponds to a dimension. The MIMO system can provide improved performance (e.g., increased transmission capacity) if the additional dimensionalities created by the multiple transmit and receive antennas are utilized.

In order to transmit data on one or more of the N_(S) eigenmodes of the MIMO channel, it is necessary to perform spatial processing at the receiver and typically also at the transmitter. The data streams transmitted from the N_(T) transmit antennas interfere with each other at the receive antennas. The spatial processing attempts to separate out the data streams at the receiver so that they can be individually recovered.

To perform spatial processing, an accurate estimate of the channel response between the transmitter and receiver is typically required. For a TDD system, the downlink (i.e., forward link) and uplink (i.e., reverse link) between an access point and a user terminal both share the same frequency band. In this case, the downlink and uplink channel responses may be assumed to be reciprocal of one another, after calibration has been performed (as described below) to account for differences in the transmit and receive chains at the access point and user terminal. That is, if H represents the channel response matrix from antenna array A to antenna array B, then a reciprocal channel implies that the coupling from array B to array A is given by H^(T), where M^(T) denotes the transpose of M.

The channel estimation and spatial processing for a MIMO system typically consume a large portion of the system resources. There is therefore a need in the art for techniques to efficiently perform channel estimation and spatial processing in a TDD MIMO system.

SUMMARY

Techniques are provided herein to perform channel estimation and spatial processing in an efficient manner in a TDD MIMO system. For the TDD MIMO system, the reciprocal channel characteristics can be exploited to simplify the channel estimation and spatial processing at both the transmitter and receiver. Initially, an access point and a user terminal in the system may perform calibration to determine differences in the responses of their transmit and receive chains and to obtain correction factors used to account for the differences. Calibration may be performed to ensure that the “calibrated” channel, with the correction factors applied, is reciprocal. In this way, a more accurate estimate of a second link may be obtained based on an estimate derived for a first link.

During normal operation, a MIMO pilot is transmitted (e.g., by the access point) on the first link (e.g., the downlink) and used to derive an estimate of the channel response for the first link. The channel response estimate may then be decomposed (e.g., by the user terminal, using singular value decomposition) to obtain a diagonal matrix of singular values and a first unitary matrix containing both the left eigenvectors of the first link and the right eigenvectors of the second link (e.g., the uplink). The first unitary matrix may thus be used to perform spatial processing for data transmission received on the first link as well as for data transmission to be sent on the second link.

A steered reference may be transmitted on the second link using the eigenvectors in the first unitary matrix. A steered reference (or steered pilot) is a pilot transmitted on specific eigenmodes using the eigenvectors used for data transmission. This steered reference may then be processed (e.g., by the access point) to obtain the diagonal matrix and a second unitary matrix containing both the left eigenvectors of the second link and the right eigenvectors of the first link. The second unitary matrix may thus be used to perform spatial processing for data transmission received on the second link as well as for data transmission to be sent on the first link.

Various aspects and embodiments of the invention are described in further detail below.

BRIEF DESCRIPTION OF THE DRAWINGS

The various aspects and features of the present invention are described below in conjunction with the following drawings, in which:

FIG. 1 is a block diagram of an access point and a user terminal in a TDD MIMO system, in accordance with one embodiment of the invention;

FIG. 2A shows a block diagram of the transmit and receive chains at the access point and user terminal, in accordance with one embodiment of the invention;

FIG. 2B shows application of correction matrices to account for differences in the transmit/receive chains at the access point and user terminal, in accordance with one embodiment of the invention;

FIG. 3 shows the spatial processing for the downlink and uplink for a spatial multiplexing mode, in accordance with one embodiment of the invention;

FIG. 4 shows the spatial processing for the downlink and uplink for a beam-steering mode, in accordance with one embodiment of the invention; and

FIG. 5 shows a process for performing channel estimation and spatial processing at the access point and user terminal, in accordance with one embodiment of the invention.

DETAILED DESCRIPTION

FIG. 1 is a block diagram of an embodiment of an access point 110 and a user terminal 150 in a TDD MIMO system 100. Access point 110 is equipped with N_(ap) transmit/receive antennas for data transmission/reception, and user terminal 150 is equipped with N_(ut) transmit/receive antennas.

On the downlink, at access point 110, a transmit (TX) data processor 114 receives traffic data (i.e., information bits) from a data source 112 and signaling and other data from a controller 130. TX data processor 114 formats, codes, interleaves, and modulates (i.e., symbol maps) the data to provide modulation symbols. A TX spatial processor 120 receives the modulation symbols from TX data processor 114 and performs spatial processing to provide N_(ap) streams of transmit symbols, one stream for each antenna. TX spatial processor 120 also multiplexes in pilot symbols as appropriate (e.g., for calibration and normal operation).

Each modulator (MOD) 122 (which includes a transmit chain) receives and processes a respective transmit symbol stream to provide a corresponding downlink modulated signal. The N_(ap) downlink modulated signals from modulators 122 a through 122 ap are then transmitted from N_(ap) antennas 124 a through 124 ap, respectively.

At user terminal 150, N_(ut) antennas 152 a through 152 ut receive the transmitted downlink modulated signals, and each antenna provides a received signal to a respective demodulator (DEMOD) 154. Each demodulator 154 (which includes a receive chain) performs processing complementary to that performed at modulator 122 and provides received symbols. A receive (RX) spatial processor 160 then performs spatial processing on the received symbols from all demodulators 154 a through 154 ut to provide recovered symbols, which are estimates of the modulation symbols sent by the access point. An RX data processor 170 further processes (e.g., symbol demaps, deinterleaves, and decodes) the recovered symbols to provide decoded data. The decoded data may include recovered traffic data, signaling, and so on, which may be provided to a data sink 172 for storage and/or a controller 180 for further processing.

The processing for the uplink may be the same or different from the processing for the downlink. Data and signaling are processed (e.g., coded, interleaved, and modulated) by a TX data processor 188 and further spatially processed by a TX spatial processor 190, which also multiplexes in pilot symbols as appropriate (e.g., for calibration and normal operation). The pilot and transmit symbols from TX spatial processor 190 are further processed by modulators 154 a through 154 ut to generate N_(ut) uplink modulated signals, which are then transmitted via antennas 152 a through 152 ut to the access point.

At access point 110, the uplink modulated signals are received by antennas 124 a through 124 ap, demodulated by demodulators 122 a through 122 ap, and processed by an RX spatial processor 140 and an RX data processor 142 in a complementary manner to that performed at the user terminal. The decoded data for the uplink may be provided to a data sink 144 for storage and/or controller 130 for further processing.

Controllers 130 and 180 control the operation of various processing units at the access point and user terminal, respectively. Memory units 132 and 182 store data and program codes used by controllers 130 and 180, respectively.

1. Calibration

For a TDD system, since the downlink and uplink share the same frequency band, a high degree of correlation normally exists between the downlink and uplink channel responses. Thus, the downlink and uplink channel response matrices may be assumed to be reciprocal (i.e., transpose) of each other. However, the responses of the transmit/receive chains at the access point are typically not equal to the responses of the transmit/receive chains at the user terminal. For improved performance, the differences may be determined and accounted for via calibration.

FIG. 2A shows a block diagram of the transmit and receive chains at access point 110 and user terminal 150, in accordance with one embodiment of the invention. For the downlink, at access point 110, symbols (denoted by a “transmit” vector x_(dn)) are processed by a transmit chain 214 and transmitted from N_(ap) antennas 124 over the MIMO channel. At user terminal 150, the downlink signals are received by N_(ut) antennas 152 and processed by a receive chain 254 to provide received symbols (denoted by a “receive” vector r_(dn)). For the uplink, at user terminal 150, symbols (denoted by a transmit vector x_(up)) are processed by a transmit chain 264 and transmitted from N_(ut) antennas 152 over the MIMO channel. At access point 110, the uplink signals are received by N_(ap) antennas 124 and processed by a receive chain 224 to provide received symbols (denoted by a receive vector r_(up)).

For the downlink, the receive vector r_(dn), at the user terminal (in the absence of noise) may be expressed as: r_(dn)=R_(ut)HT_(ap)x_(dn,)   Eq (1)

-   -   where x_(dn) is the transmit vector with N_(ap) entries for the         downlink;     -   r_(dn) is the receive vector with N_(ut) entries;     -   T_(ap) is an N_(ap)×N_(ap) diagonal matrix with entries for the         complex gains associated with the transmit chain for the N_(ap)         antennas at the access point;     -   R_(ut) is an N_(ut)×N_(ut) diagonal matrix with entries for the         complex gains associated with the receive chain for the N_(ut)         antennas at the user terminal; and     -   H is an N_(ut)×N_(ap) channel response matrix for the downlink.         The responses of the transmit/receive chains and the MIMO         channel are typically a function of frequency. For simplicity, a         flat-fading channel (i.e., with a flat frequency response) is         assumed for the following derivation.

For the uplink, the receive vector r_(up) at the access point (in the absence of noise) may be expressed as: r_(up)=R_(ap)H^(T)T_(ut,)   Eq (2)

-   -   where x_(up) is the transmit vector with N_(ut) entries for the         uplink;     -   r_(up) is the receive vector with N_(ap) entries;     -   T_(ut) is an N_(ut)×N_(ut) diagonal matrix with entries for the         complex gains associated with the transmit chain for the N_(ut)         antennas at the user terminal;     -   R_(ap) is an N_(ap)×N_(ap) diagonal matrix with entries for the         complex gains associated with the receive chain for the N_(ap)         antennas at the access point; and     -   H^(T) is an N_(ap)×N_(ut) channel response matrix for the         uplink.

From equations (1) and (2), the “effective” downlink and uplink channel responses, H_(dn) and H_(up), which include the responses of the applicable transmit and receive chains, may be expressed as: H_(dn)=R_(ut)HT_(ap) and H_(up)=R_(ap)H^(T)T_(ut.)   Eq (3) As shown in equation (3), if the responses of the transmit/receive chains at the access point are not equal to the responses of the transmit/receive chains at the user terminal, then the effective downlink and uplink channel responses are not reciprocal of one another, i.e., R_(ut)HT_(ap)≠(R_(ap)H^(T)T_(ut))^(T).

Combining the two equations in equation set (3), the following relationship may be obtained: H=R_(ut) ⁻¹H_(dn)T_(ut) ⁻¹=(R_(ap) ⁻¹H_(up)T_(ut) ⁻¹)^(T)=T_(ut) ¹H_(up) ^(T)R_(ap) ^(−1.)   Eq (4) Rearranging equation (4), the following is obtained: H_(up) ^(T)=T_(ut)R_(ut) ⁻¹H_(dn)T_(ap) ⁻¹R_(ap)=K_(ut) ⁻¹H_(dn)K_(ap) or H_(up)=(K_(ut) ⁻¹H_(dn)K_(ap))^(T,)   Eq (5) where K_(ut)=T_(ut) ⁻¹R_(ut) and K_(ap)=T_(ap) ⁻¹R_(ap). Because T_(ut), R_(ut), T_(ap), and R_(ap) are diagonal matrices, K_(ap) and K_(ut) are also diagonal matrices. Equation (5) may also be expressed as: H_(up)K_(ut)=(H_(dn)K_(ap))^(T).   Eq (6)

The matrices K_(ap) and K_(ut) may be viewed as including “correction factors” that can account for differences in the transmit/receive chains at the access point and user terminal. This would then allow the channel response for one link to be expressed by the channel response for the other link, as shown in equation (5).

Calibration may be performed to determine the matrices K_(ap) and K_(ut). Typically, the true channel response H and the transmit/receive chain responses are not known nor can they be exactly or easily ascertained. Instead, the effective downlink and uplink channel responses, H_(dn) and H_(up), may be estimated based on MIMO pilots sent on the downlink and uplink, respectively. The generation and use of MIMO pilot are described in detail in the aforementioned U.S. patent application Ser. No. 60/421,309.

Estimates of the matrices K_(ap) and K_(ut), which are referred to as correction matrices, {circumflex over (K)}_(ap) and {circumflex over (K)}_(ut), may be derived based on the downlink and uplink channel response estimates, Ĥ_(dn) and Ĥ_(up), in various manners, including by a matrix-ratio computation and a minimum mean square error (MMSE) computation. For the matrix-ratio computation, an (N_(ut)×N_(ap)) matrix C is first computed as a ratio of the uplink and downlink channel response estimates, as follows: $\begin{matrix} {{\underset{\_}{C} = \frac{{\hat{\underset{\_}{H}}}_{up}^{T}}{{\underset{\_}{\hat{H}}}_{dn}}},} & {{Eq}\quad(7)} \end{matrix}$ where the ratio is taken element-by-element. Each element of C may thus be computed as: ${c_{i,j} = \frac{{\hat{h}}_{{{up}\quad i},j}}{{\hat{h}}_{{{dn}\quad i},j}}},{for}$ i = {1  …  N_(ut)} and j = {1  …  N_(ap)}, where ĥ_(up i,j) and ĥ_(dn i,j) are the (i,j)-th (row, column) element of Ĥ_(up) ^(T) and Ĥ_(dn), respectively, and C_(i,j) is the ( i,j )-th element of C.

A correction vector for the access point, {circumflex over (k)}_(ap), which includes only the N_(ap) diagonal elements of {circumflex over (K)}_(ap), may be defined to be equal to the mean of the normalized rows of C. Each row of C, c_(i), is first normalized by dividing each element of the row with the first element of the row to obtain a corresponding normalized row, {tilde over (c)}_(i). Thus, if c_(i)(k)=[c_(i,1). . . c_(i,N) _(ap) ] is the i-th row of C, then the normalized row {tilde over (c)}_(i) may be expressed as: {tilde over (c)} _(i)(k)=[c _(i,1)(k)/c _(i,1)(k) . . . c _(i,j)(k)/c _(i,1)(k) . . . c _(i,N) _(ap) (k)/c _(i,1)(k)] The correction vector {circumflex over (k)}_(ap)(k) is then set equal to the mean of the N_(ut) normalized rows of C and may be expressed as: $\begin{matrix} {{\underset{\_}{\hat{k}}}_{ap} = {\frac{1}{N_{ut}}{\sum\limits_{i = 1}^{N_{ut}}\quad{{\underset{\_}{\overset{\sim}{c}}}_{i}.}}}} & {{Eq}\quad(8)} \end{matrix}$ Because of the normalization, the first element of {circumflex over (k)}_(ap)(k) is unity.

A correction vector {circumflex over (k)}_(ut)(k) for the user terminal, {circumflex over (k)}_(ut)(k), which includes only the N_(ut) diagonal elements of {circumflex over (K)}ut(k), may be defined to be equal to the mean of the inverses of the normalized columns of C. Each column of C, c_(j), is first normalized by scaling each element in the column with thej-th element of the vector {circumflex over (k)}_(ap), which is denoted as K_(ap,j,j), to obtain a corresponding normalized column, {hacek over (c)}_(j). Thus, if c_(j)(k)=[c_(i,j). . . c_(N) _(ut,) _(j)]^(T) is the j-th column of C, then the normalized column {hacek over (c)}_(j) may be expressed as: {hacek over (c)} _(j) =[c _(1,j) /K _(ap,j,j) . . . c _(i,j) /K _(ap,j,j) . . . c _(N) _(ut) _(,j) /K _(ap,j,j)]T. The correction vector {circumflex over (k)}_(ap) is then set equal to the mean of the inverses of the N_(ap) normalized columns of C and may be expressed as: $\begin{matrix} {{{\underset{\_}{\hat{k}}}_{ut} = {\frac{1}{N_{ap}}{\sum\limits_{j = 1}^{N_{ap}}\quad\frac{1}{{\overset{\Cup}{\underset{\_}{c}}}_{j}}}}},} & {{Eq}\quad(9)} \end{matrix}$ where the inversion of the normalized columns, {hacek over (c)}_(j)(k), is performed element-wise. The calibration provides the correction vectors, {circumflex over (k)}_(ap) and {circumflex over (k)}_(ut), or the corresponding correction matrices {circumflex over (K)}_(ap) and {circumflex over (K)}_(ut), for the access point and user terminal, respectively.

The MMSE computation for the correction matrices {circumflex over (K)}_(ap) and {circumflex over (K)}_(ut) is described in detail in aforementioned U.S. Patent Application Ser. No. 60/421,462.

FIG. 2B illustrates the application of the correction matrices to account for differences in the transmit/receive chains at the access point and user terminal, in accordance with one embodiment of the invention. On the downlink, the transmit vector x_(dn) is first multiplied with the matrix {circumflex over (K)}_(ap) by a unit 212. The subsequent processing by transmit chain 214 and receive chain 254 for the downlink is the same as shown in FIG. 2A. Similarly, on the uplink, the transmit vector x_(up) is first multiplied with the matrix {circumflex over (K)}_(ut) by a unit 262. Again, the subsequent processing by transmit chain 264 and receive chain 224 for the uplink is the same as shown in FIG. 2A.

The “calibrated” downlink and uplink channel responses observed by the user terminal and access point, respectively, may be expressed as: H_(cdn)=H_(dn){circumflex over (K)}_(ap) and H_(cup)=H_(up){circumflex over (K)}_(ut),   Eq(10) where H_(cdn) ^(T) and H_(cup) are estimates of the “true” calibrated channel response expressions in equation (6). From equations (6) and (10), it can be seen that H_(cup)≈H_(cdn) ^(T). The accuracy of the relationship H_(cup)≈H_(cdn) ^(T) is dependent on the accuracy of the estimates {circumflex over (K)}_(ap) and {circumflex over (K)}_(ut), which in turn is dependent on the quality of the downlink and uplink channel response estimates, Ĥ_(dn) and Ĥ_(up). As shown above, once the transmit/receive chains have been calibrated, a calibrated channel response estimate obtained for one link (e.g., Ĥ_(cdn)) may be used as an estimate of the calibrated channel response for the other link (e g., Ĥ_(cup)).

The calibration for TDD MIMO systems is described in detail in the aforementioned U.S. Patent Application Ser. No. 60/421,309 and U.S. Patent Application Ser. No. 60/421,462.

2. Spatial Processing

For a MIMO system, data may be transmitted on one or more eigenmodes of the MIMO channel. A spatial multiplexing mode may be defined to cover data transmission on multiple eigenmodes, and a beam-steering mode may be defined to cover data transmission on a single eigenmode. Both operating modes require spatial processing at the transmitter and receiver.

The channel estimation and spatial processing techniques described herein may be used for MIMO systems with and without OFDM. OFDM effectively partitions the overall system bandwidth into a number of (N_(F)) orthogonal subbands, which are also referred to as frequency bins or subchannels. With OFDM, each subband is associated with a respective subcarrier upon which data may be modulated. For a MIMO system that utilizes OFDM (i.e., a MIMO-OFDM system), each eigenmode of each subband may be viewed as an independent transmission channel. For clarity, the channel estimation and spatial processing techniques are described below for a TDD MIMO-OFDM system. For this system, each subband of the wireless channel may be assumed to be reciprocal.

The correlation between the downlink and uplink channel responses may be exploited to simplify the channel estimation and spatial processing at the access point and user terminal for a TDD system. This simplification is effective after calibration has been performed to account for differences in the transmit/receive chains. The calibrated channel responses may be expressed as a function of frequency, as follows: H _(cdn)(k)=H _(dn)(k){circumflex over (K)} _(ap)(k), for k∈K, and H _(cup)(k)=H _(up)(k){circumflex over (K)} _(ut)(k)≈(H _(dn)(k){circumflex over (K)} _(ap)(k))^(T), for k∈K,  Eq (11) where K represents a set of all subbands that may be used for data transmission (i.e., the “data subbands”). The calibration may be performed such that the matrices {circumflex over (K)}_(ap)(k) and {circumflex over (K)}_(ut)(k) are obtained for each of the data subbands. Alternatively, the calibration may be performed for only a subset of all data subbands, in which case the matrices {circumflex over (K)}_(ap)(k) and {circumflex over (K)}_(ut)(k) for the “uncalibrated” subbands may be obtained by interpolating the matrices for the “calibrated” subbands, as described in the aforementioned U.S. Patent Application Ser. No. 60/421,462.

The channel response matrix H(k) for each subband may be “diagonalized” to obtain the N_(s) eigenmodes for that subband. This may be achieved by performing either singular value decomposition on the channel response matrix H(k) or eigenvalue decomposition on the correlation matrix of H(k), which is R(k)=H^(H)(k)H(k). For clarity, singular value decomposition is used for the following description.

The singular value decomposition of the calibrated uplink channel response matrix, H_(cup)(k), may be expressed as: H _(cup)(k)=U _(ap)(k)Σ(k)V _(ut) ^(H)(k) , for k∈K,  Eq (12) where U_(ap)(k) is an (N_(ap)×N_(ap)) unitary matrix of left eigenvectors of H_(cup)(k);

-   -   Σ(k) is an (N_(ap)×N_(ut)) diagonal matrix of singular values of         H_(cup)(k); and     -   V_(ut)(k) is an (N_(ut)×N_(ut)) unitary matrix of right         eigenvectors of H_(cup)(k).         A unitary matrix is characterized by the property M^(H)M=I,         where I is the identity matrix.

Correspondingly, the singular value decomposition of the calibrated downlink channel response matrix, H_(cdn)(k), may be expressed as: H _(cdn)(k)=V _(ut)*(k)Σ(k)U _(ap) ^(T)(k), for k∈K,  Eq (13) where the matrices V_(ut)*(k) and U_(ap)*(k) are unitary matrices of left and right eigenvectors, respectively, of H_(cdn)(k). As shown in equations (12) and (13) and based on the above description, the matrices of left and right eigenvectors for one link are the complex conjugate of the matrices of right and left eigenvectors, respectively, for the other link. The matrices V_(ut)(k), V_(ut)*(k), V_(ut) ^(T)(k), and V_(ut) ^(H)(k) are different forms of the matrix V_(ut)(k), and the matrices U_(ap)(k), U_(ap)*(k), U_(ap) ^(T)(k), and U_(ap) ^(H)(k) are also different forms of the matrix U_(ap)(k). For simplicity, reference to the matrices U_(ap)(k) and V_(ut)(k) in the following description may also refer to their various other forms. The matrices U_(ap)(k) and V_(ut)(k) are used by the access point and user terminal, respectively, for spatial processing and are denoted as such by their subscripts. The eigenvectors are also often referred to as “steering” vectors.

Singular value decomposition is described in further detail by Gilbert Strang in a book entitled “Linear Algebra and Its Applications,” Second Edition, Academic Press, 1980.

The user terminal can estimate the calibrated downlink channel response based on a MIMO pilot sent by the access point. The user terminal may then perform singular value decomposition for the calibrated downlink channel response estimate Ĥ_(cdn)(k), for k ∈K, to obtain the diagonal matrix {circumflex over (Σ)}(k) and the matrix V_(ut)*(k) of left eigenvectors of Ĥ_(cdn)(k). This singular value decomposition may be given as Ĥ_(cdn)(k)={circumflex over (V)}_(ut)*(k){circumflex over (Σ)}(k)Û_(ap) ^(T)(k), where the hat (“ˆ”) above each matrix indicates that it is an estimate of the actual matrix.

Similarly, the access point can estimate the calibrated uplink channel response based on a MIMO pilot sent by the user terminal. The access point may then perform singular value decomposition for the calibrated uplink channel response estimate Ĥ_(cup)(k), for k∈K, to obtain the diagonal matrix {circumflex over (Σ)},(k) and the matrix Û_(ap)(k) of left eigenvectors of Ĥcup(k). This singular value decomposition may be given as Ĥcup(k)=Û_(ap)(k){circumflex over (Σ)}(k){circumflex over (V)}_(ut) ^(H)(k).

However, because of the reciprocal channel and the calibration, the singular value decomposition only needs to be performed by either the user terminal or the access point. If performed by the user terminal, then the matrix {circumflex over (V)}_(ut)(k), for k∈K, are used for spatial processing at the user terminal and the matrix Û_(ap)(k), for k∈K, may be provided to the access point in either a direct form (i.e., by sending entries of the matrices Û_(ap)(k) ) or an indirect form (e.g., via a steered reference, as described below).

The singular values in each matrix {circumflex over (Σ)}(k), for k∈K, may be ordered such that the first column contains the largest singular value, the second column contains the next largest singular value, and so on (i.e., σ₁≧σ₂≧. . .≧σ_(N) _(s) , where σis the eigenvalue in the i-th column of {circumflex over (Σ)}(k) after the ordering). When the singular values for each matrix {circumflex over (Σ)}(k) are ordered, the eigenvectors (or columns) of the associated unitary matrices {circumflex over (V)}_(ut)(k) and Û_(ap)(k) for that subband are also ordered correspondingly. A “wideband” eigenmode may be defined as the set of same-order eigenmode of all subbands after the ordering (i.e., the m-th wideband eigenmode includes the m-th eigenmode of all subbands). Each wideband eigenmode is associated with a respective set of eigenvectors for all of the subbands. The principle wideband eigenmode is the one associated with the largest singular value in each matrix {circumflex over (Σ)}(k) after the ordering.

A. Uplink Spatial Processing

The spatial processing by the user terminal for an uplink transmission may be expressed as: x _(up)(k)={circumflex over (K)} _(ut)(k){circumflex over (V)} _(ut)(k)s _(up)(k), for k∈K,  Eq (14)

-   -   where x_(up)(k) is the transmit vector for the uplink for the         k-th subband; and     -   s_(up)(k) is a “data” vector with up to N_(s) non-zero entries         for the modulation symbols to be transmitted on the N_(s)         eigenmodes of the k-th subband.

The received uplink transmission at the access point may be expressed as: $\begin{matrix} {\begin{matrix} {\quad{{{\underset{\_}{r}}_{up}(k)} = {{{{\underset{\_}{H}}_{\quad{up}}(k)}{{\underset{\_}{x}}_{\quad{up}}(k)}} + {{\underset{\_}{n}}_{\quad{up}}(k)}}}} \\ {= {{{{\underset{\_}{H}}_{up}(k)}{{\hat{\underset{\_}{K}}}_{ut}(k)}{{\hat{\underset{\_}{V}}}_{ut}(k)}{{\underset{\_}{s}}_{up}(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {\approx {{{{\hat{\underset{\_}{H}}}_{cup}(k)}{{\hat{\underset{\_}{V}}}_{ut}(k)}{{\underset{\_}{s}}_{up}(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {= {{{{\hat{\underset{\_}{U}}}_{ap}(k)}{\hat{\underset{\_}{\Sigma}}(k)}{{\hat{\underset{\_}{V}}}_{ut}^{H}(k)}{{\hat{\underset{\_}{V}}}_{ut}(k)}{{\underset{\_}{s}}_{up}(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {= {{{{\hat{\underset{\_}{U}}}_{ap}(k)}{\hat{\underset{\_}{\Sigma}}(k)}{{\underset{\_}{s}}_{up}(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \end{matrix},{{{for}\quad k} \in {K.}}} & {{Eq}\quad(15)} \end{matrix}$

-   -   where r_(up)(k) is the received vector for the uplink for the         k-th subband; and     -   n_(up)(k) is additive white Gaussian noise (AWGN) for the k-th         subband.         Equation (15) uses the following relationships:         H_(up)(k){circumflex over (K)}_(up)(k)=H_(cup)(k)≈Ĥ_(cup)(k) and         Ĥ_(cup)(k)=Û_(ap)(k){circumflex over (Σ)}(k){circumflex over         (V)}_(ut)(k).

A weighted matched filter matrix M_(ap)(k) for the uplink transmission from the user terminal may be expressed as: M _(ap)(k)={circumflex over (Σ)}⁻¹(k)Û _(ap) ^(H)(k), for k∈K.  Eq (16) The spatial processing (or matched filtering) at the access point for the received uplink transmission may be expressed as: $\begin{matrix} {\begin{matrix} {{{\hat{\underset{\_}{s}}}_{up}(k)} = {{{\hat{\underset{\_}{\Sigma}}}^{- 1}(k)}{{\hat{\underset{\_}{U}}}_{ap}^{H}(k)}{{\underset{\_}{r}}_{up}(k)}}} \\ {= {{{\hat{\underset{\_}{\Sigma}}}^{- 1}(k)}{{\hat{\underset{\_}{U}}}_{ap}^{H}(k)}\left( {{{{\hat{\underset{\_}{U}}}_{ap}(k)}{\hat{\underset{\_}{\Sigma}}(k)}{{\underset{\_}{s}}_{up}(k)}} + {{\underset{\_}{n}}_{up}(k)}} \right)}} \\ {= {{{\underset{\_}{s}}_{up}(k)} + {{\overset{\sim}{\underset{\_}{n}}}_{up}(k)}}} \end{matrix},{{{for}\quad k} \in K},} & {{Eq}\quad(17)} \end{matrix}$ where ŝ_(up)(k) is an estimate of the data vector s_(up)(k) transmitted by the user terminal on the uplink, and ñ_(up)(k) is the post-processed noise.

B. Downlink Spatial Processing

The spatial processing by the access point for a downlink transmission may be expressed as: x _(dn)(k)={circumflex over (K)} _(ap)(k)Û _(ap)*(k)s _(dn)(k), for k∈K,  Eq (18) where x_(dn)(k) is the transmit vector and s_(dn)(k) is the data vector for the downlink.

The received downlink transmission at the user terminal may be expressed as: $\begin{matrix} {\begin{matrix} {{{\underset{\_}{r}}_{dn}(k)} = {{{{\underset{\_}{H}}_{dn}(k)}{{\underset{\_}{x}}_{dn}(k)}} + {{\underset{\_}{n}}_{dn}(k)}}} \\ {= {{{{\underset{\_}{H}}_{dn}(k)}{{\hat{\underset{\_}{K}}}_{ap}(k)}{{\hat{\underset{\_}{U}}}_{ap}^{*}(k)}{{\underset{\_}{s}}_{dn}(k)}} + {{\underset{\_}{n}}_{dn}(k)}}} \\ {\approx {{{{\hat{\underset{\_}{H}}}_{cdn}(k)}{{\hat{\underset{\_}{U}}}_{ap}^{*}(k)}{{\underset{\_}{s}}_{dn}(k)}} + {{\underset{\_}{n}}_{dn}(k)}}} \\ \left. {= {{{{\hat{\underset{\_}{V}}}_{ut}^{*}(k)}{\hat{\underset{\_}{\Sigma}}(k)}{{\hat{\underset{\_}{U}}}_{ap}^{T}(k)}{{\hat{\underset{\_}{U}}}_{ap}^{*}(k)}{{\underset{\_}{s}}_{dn}(k)}} + {{\underset{\_}{n}}_{dn}(k)}}} \right) \\ {= {{{{\hat{\underset{\_}{V}}}_{ut}^{*}(k)}{\hat{\underset{\_}{\Sigma}}(k)}{{\underset{\_}{s}}_{dn}(k)}} + {{\underset{\_}{n}}_{dn}(k)}}} \end{matrix},{{{for}\quad k} \in {K.}}} & {{Eq}\quad(19)} \end{matrix}$

A weighted matched filter matrix M_(ut)(k) for the downlink transmission from the access point may be expressed as: M _(ut)(k)={circumflex over (Σ)}⁻¹(k){circumflex over (V)} _(ut) ^(T)(k), for k 531 K.  Eq (20) The spatial processing (or matched filtering) at the user terminal for the received downlink transmission may be expressed as: $\begin{matrix} {\begin{matrix} {{{\hat{\underset{\_}{s}}}_{dn}(k)} = {{{\hat{\underset{\_}{\Sigma}}}^{- 1}(k)}{{\hat{\underset{\_}{V}}}_{ut}^{T}(k)}{{\underset{\_}{r}}_{dn}(k)}}} \\ {= {{{\hat{\underset{\_}{\Sigma}}}^{- 1}(k)}{{\hat{\underset{\_}{V}}}_{ut}^{T}(k)}\left( {{{{\hat{\underset{\_}{V}}}_{ut}^{*}(k)}{\hat{\underset{\_}{\Sigma}}(k)}{{\underset{\_}{s}}_{dn}(k)}} + {{\underset{\_}{n}}_{dn}(k)}} \right)}} \\ {= {{{\underset{\_}{s}}_{dn}(k)} + {{\overset{\sim}{\underset{\_}{n}}}_{dn}(k)}}} \end{matrix},{{{for}\quad k} \in {K.}}} & {{Eq}\quad(21)} \end{matrix}$

Table 1 summarizes the spatial processing at the access point and user terminal for data transmission and reception. TABLE 1 Uplink Downlink User Transmit: Receive: Termi- x _(up) (k) = {circumflex over (K)} _(ut) (k){circumflex over (V)} _(ut) (k)s _(up) (k) ŝ _(dn) (k) = {circumflex over (Σ)} ⁻¹(k){circumflex over (V)} _(ut) ^(T) (k)r _(dn) (k) nal Access Receive: Transmit: Point ŝ _(up) (k) = {circumflex over (Σ)} ⁻¹(k)Û _(ap) ^(H)(k)r _(up) (k) x _(dn) (k) = {circumflex over (K)} _(ap) (k)Û _(ap)* (k)s _(dn) (k)

In the above description and as shown in Table 1, the correction matrices {circumflex over (K)}_(ap)(k) and {circumflex over (K)}_(ut)(k) are applied on the transmit side at the access point and user terminal, respectively. The correction matrices {circumflex over (K)}_(ap)(k) and {circumflex over (K)}_(ut)(k) may also be combined with other diagonal matrices (e.g., such as weight matrices W_(dn)(k) and W_(up)(k) used to achieve channel inversion). However, the correction matrices may also be applied on the receive side, instead of the transmit side, and this is within the scope of the invention.

FIG. 3 is a block diagram of the spatial processing for the downlink and uplink for the spatial multiplexing mode, in accordance with one embodiment of the invention.

For the downlink, within a TX spatial processor 120 x at access point 110 x, the data vector s_(dn)(k), for k∈K , is first multiplied with the matrix Û_(ap)*(k) by a unit 310 and then further multiplied with the correction matrix {circumflex over (K)}_(ap)(k) by a unit 312 to obtain the transmit vector x_(dn)(k). The vector x_(dn)(k), for k∈K, is then processed by a transmit chain 314 within modulator 122 x and transmitted over the MIMO channel to user terminal 150 x. Unit 310 performs the spatial processing for the downlink data transmission.

At user terminal 150 x, the downlink signals are processed by a receive chain 354 within demodulator 154 x to obtain the receive vector r_(dn)(k), for k∈K. Within an RX spatial processor 160 x, the receive vector r_(dn)(k), for k∈K, is first multiplied with the matrix {circumflex over (V)}_(ut)(k) by a unit 356 and further scaled by the inverse diagonal matrix {circumflex over (Σ)}⁻¹(k) by a unit 358 to obtain the vector ŝ_(dn)(k), which is an estimate of the data vector s_(dn)(k). Units 356 and 358 perform the spatial processing for the downlink matched filtering.

For the uplink, within a TX spatial processor 190 x at user terminal 150 x, the data vector s_(up)(k), for k∈K , is first multiplied with the matrix {circumflex over (V)}_(ut)(k) by a unit 360 and then further multiplied with the correction matrix {circumflex over (K)}_(ut)(k) by a unit 362 to obtain the transmit vector x_(up)(k). The vector x_(up)(k), for k∈K, is then processed by a transmit chain 364 within modulator 154 x and transmitted over the MIMO channel to access point 110 x. Unit 360 performs the spatial processing for the uplink data transmission.

At access point 110 x, the uplink signals are processed by a receive chain 324 within demodulator 122 x to obtain the receive vector r_(up)(k), for k∈K. Within an RX spatial processor 140 x, the receive vector r_(up)(k), for k∈K , is first multiplied with the matrix Û_(ap) ^(H)(k) by a unit 326 and further scaled by the inverse diagonal matrix {circumflex over (Σ)}⁻¹(k) by a unit 328 to obtain the vector ŝ_(up)(k), which is an estimate of the data vector s_(up)(k). Units 326 and 328 perform the spatial processing for the uplink matched filtering.

3. Beam-Steering

For certain channel conditions, it is better to transmit data on only one wideband eigenmode—typically the best or principal wideband eigenmode. This may be the case if the received signal-to-noise ratios (SNRs) for all other wideband eigenmodes are sufficiently poor so that improved performance is achieved by using all of the available transmit power on the principal wideband eigenmode.

Data transmission on one wideband eigenmode may be achieved using either beam-forming or beam-steering. For beam-forming, the modulation symbols are spatially processed with the eigenvectors {circumflex over (v)}_(ut,1)(k) or û_(ap,1)(k), for k∈K, for the principal wideband eigenmode (i.e., the first column of {circumflex over (V)}_(ut)(k) or Û_(ap)(k), after the ordering). For beam-steering, the modulation symbols are spatially processed with a set of “normalized” (or “saturated”) eigenvectors {tilde over (v)}_(ut)(k) or ũ_(ap)(k), for k∈K, for the principal wideband eigenmode. For clarity, beam-steering is described below for the uplink.

For the uplink, the elements of each eigenvector {circumflex over (v)}_(ut,1)(k), for k∈K, for the principal wideband eigenmode may have different magnitudes. Thus, the preconditioned symbols for each subband, which are obtained by multiplying the modulation symbol for subband k with the elements of the eigenvector {circumflex over (v)}_(ut,1)(k) for subband k, may then have different magnitudes. Consequently, the per-antenna transmit vectors, each of which includes the preconditioned symbols for all data subbands for a given transmit antenna, may have different magnitudes. If the transmit power for each transmit antenna is limited (e.g., because of limitations of power amplifiers), then beam-forming may not fully use the total power available for each antenna.

Beam-steering uses only the phase information from the eigenvectors {circumflex over (v)}_(ut,1)(k), for k∈K, for the principal wideband eigenmode and normalizes each eigenvector such that all elements in the eigenvector have equal magnitudes. The normalized eigenvector {tilde over (v)}_(ut)(k) for the k-th subband may be expressed as: {tilde over (v)} _(ut)(k)=[Ae ^(jθ) ² ^((k)) Ae ^(jθ) ² ^((k)) . . . Ae ^(jθ) ^(Nut) ^((k)]) ^(T,)  Eq (22) where A is a constant (e.g., A =1); and

-   -   θ_(i)(k) is the phase for the k-th subband of the i-th transmit         antenna,     -   which is given as: $\begin{matrix}         {{\theta_{i}(k)} = {{\angle\quad{{\hat{v}}_{{ut},1,i}(k)}} = {{\tan^{- 1}\left( \frac{{Im}\left\{ {{\hat{v}}_{{ut},1,i}(k)} \right\}}{{Re}\left\{ {{\hat{v}}_{{ut},1,i}(k)} \right\}} \right)}.}}} & {{Eq}\quad(23)}         \end{matrix}$         As shown in equation (23), the phase of each element in the         vector {tilde over (v)}_(ut)(k) is obtained from the         corresponding element of the eigenvector {circumflex over         (v)}_(ut,1)(k) (i.e., θ_(i)(k) is obtained from {circumflex over         (v)}_(ut,1,i)(k) , where {circumflex over         (v)}_(ut,1)(k)=[{circumflex over (v)}_(ut,1,1)(k) {circumflex         over (v)}_(ut,1,2)(k) . . . {circumflex over (v)}_(ut,1,N) _(ut)         (k)]^(T) ).

A. Uplink Beam-Steering

The spatial processing by the user terminal for beam-steering on the uplink may be expressed as: {tilde over (x)} _(up)(k)={circumflex over (K)} _(ut) {tilde over (v)} _(ut)(k)s _(up)(k), for k∈K,  Eq (24) where s_(up)(k) is the modulation symbol to be transmitted on the k-th subband; and

{tilde over (x)}_(up)(k) is the transmit vector for the k-th subband for beam-steering.

As shown in equation (22), the N_(ut) elements of the normalized steering vector {tilde over (v)}_(ut)(k) for each subband have equal magnitude but possibly different phases. The beam-steering thus generates one transmit vector {tilde over (x)}_(up)(k) for each subband, with the N_(ut) elements of {tilde over (x)}_(up)(k) having the same magnitude but possibly different phases.

The received uplink transmission at the access point for beam-steering may be expressed as: $\begin{matrix} {\begin{matrix} {{{\overset{\sim}{\underset{\_}{r}}}_{up}(k)} = {{{{\underset{\_}{H}}_{up}(k)}{{\overset{\sim}{\underset{\_}{x}}}_{up}(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {= {{{{\underset{\_}{H}}_{up}(k)}{{\hat{\underset{\_}{K}}}_{ut}(k)}{{\overset{\sim}{\underset{\_}{v}}}_{ut}(k)}{s_{up}(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {= {{{{\underset{\_}{H}}_{cup}(k)}{{\overset{\sim}{\underset{\_}{v}}}_{ut}(k)}{s_{up}(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \end{matrix},{{{for}\quad k} \in K},} & {{Eq}\quad(25)} \end{matrix}$ where {tilde over (r)}_(up)(k) is the received vector for the uplink for the k-th subband for beam-steering.

A matched filter row vector {tilde over (m)}_(ap)(k) for the uplink transmission using beam-steering. may be expressed as: {tilde over (m)} _(ap)(k)=(H _(cup)(k){tilde over (v)} _(ut)(k))^(H), for k∈K.  Eq (26) The matched filter vector {tilde over (m)}_(ap)(k) may be obtained as described below. The spatial processing (or matched filtering) at the access point for the received uplink transmission with beam-steering may be expressed as: $\begin{matrix} \begin{matrix} {{{\hat{s}}_{up}(k)} = {{{\overset{\sim}{\lambda}}_{up}^{- 1}(k)}{{\overset{\sim}{\underset{\_}{m}}}_{ap}(k)}{{\overset{\sim}{\underset{\_}{r}}}_{up}(k)}}} \\ {= {{{\overset{\sim}{\lambda}}_{up}^{- 1}(k)}\left( {{{\underset{\_}{H}}_{cup}(k)}{{\overset{\sim}{\underset{\_}{v}}}_{ut}(k)}} \right)^{H}\left( {{{{\underset{\_}{H}}_{cup}(k)}{{\overset{\sim}{\underset{\_}{v}}}_{ut}(k)}s_{up}(k)} +} \right.}} \\ {\left. {{\underset{\_}{n}}_{up}(k)} \right),{{{for}\quad k} \in K},} \\ {= {{s_{up}(k)} + {{\overset{\sim}{n}}_{up}(k)}}} \end{matrix} & {{Eq}\quad(27)} \end{matrix}$

-   -   where {tilde over (λ)}_(up)(k)=(H_(cup)(k){tilde over         (v)}ut(k))^(H)(H_(cup)(k){tilde over (v)}_(ut)(k)) (i.e., {tilde         over (λ)}_(up)(k) is the inner product of {tilde over         (m)}_(ap)(k) and its conjugate transpose),     -   ŝ_(up)(k) is an estimate of the modulation symbol s_(up)(k)         transmitted by the user terminal on the uplink, and     -   ñ_(up)(k) is the post-processed noise.

B. Downlink Beam-Steering

The spatial processing by the access point for beam-steering on the downlink may be expressed as: {tilde over (x)} _(dn)(k)={circumflex over (K)} _(ap) ũ _(ap)(k)s _(dn)(k), for k∈K,  Eq (28) where ũ_(ap)(k) is the normalized eigenvector for the k-th subband, which is generated based on the eigenvector û_(ap,1)*(k), for the principal wideband eigenmode, as described above.

A matched filter row vector {tilde over (m)}_(ut)(k) for the downlink transmission using beam-steering may be expressed as: {tilde over (m)} _(ut)(k)=(H _(cdn)(k)ũ _(ap)(k))^(H), for k∈K.  Eq (29) The spatial processing (or matched filtering) at the user terminal for the received downlink transmission may be expressed as: $\begin{matrix} \begin{matrix} {{{\hat{s}}_{dn}(k)} = {{{\overset{\sim}{\lambda}}_{dn}^{- 1}(k)}{{\overset{\sim}{\underset{\_}{m}}}_{ut}(k)}{{\overset{\sim}{\underset{\_}{r}}}_{dn}(k)}}} \\ {= {{{\overset{\sim}{\lambda}}_{dn}^{- 1}(k)}\left( {{{\underset{\_}{H}}_{cdn}(k)}{{\overset{\sim}{\underset{\_}{u}}}_{ap}(k)}} \right)^{H}\left( {{{{\underset{\_}{H}}_{cdn}(k)}{{\overset{\sim}{\underset{\_}{u}}}_{ap}(k)}s_{up}(k)} +} \right.}} \\ {\left. {{\underset{\_}{n}}_{dn}(k)} \right),{{{for}\quad k} \in K},} \\ {= {{s_{dn}(k)} + {{\overset{\sim}{n}}_{dn}(k)}}} \end{matrix} & {{Eq}\quad(30)} \end{matrix}$ where {tilde over (λ)}_(dn)(k)=(H_(cdn)(k)ũ_(ap)(k))^(H)(H_(cdn)(k)ũ_(ap)(k)) (i.e., {tilde over (λ)}_(dn)(k) is the inner product of {tilde over (m)}_(ut)(k) and its conjugate transpose).

Beam-steering may be viewed as a special case of spatial processing in which only one eigenvector for one eigenmode is used for data transmission and this eigenvector is normalized to have equal magnitudes.

FIG. 4 is a block diagram of the spatial processing for the downlink and uplink for the beam-steering mode, in accordance with one embodiment of the invention.

For the downlink, within a TX spatial processor 120 y at access point 110 y, the modulation symbol s_(dn)(k), for k∈K, is first multiplied with the normalized eigenvector ũ_(ap)(k) by a unit 410 and then further multiplied with the correction matrix {circumflex over (K)}_(ap)(k) by a unit 412 to obtain the transmit vector {tilde over (x)}_(dn)(k). The vector {tilde over (x)}dn(k), for k ∈K, is then processed by a transmit chain 414 within modulator 122 y and transmitted over the MIMO channel to user terminal 150 y. Unit 410 performs spatial processing for the downlink data transmission for the beam-steering mode.

At user terminal 150 y, the downlink signals are processed by a receive chain 454 within demodulator 154 y to obtain the receive vector {tilde over (r)}_(dn)(k), for k∈K. Within an RX spatial processor 160 y, a unit 456 performs an inner product of the receive vector {tilde over (r)}_(dn)(k) , for k∈K, with the matched filter vector {tilde over (m)}_(ut)(k). The inner product result is then scaled by {tilde over (λ)}_(dn) ⁻¹(k) by a unit 458 to obtain the symbol ŝ_(dn)(k), which is an estimate of the modulation symbol s_(dn)(k). Units 456 and 458 perform spatial processing for the downlink matched filtering for the beam-steering mode.

For the uplink, within a TX spatial processor 190 y at user terminal 150 y, the modulation symbol s_(up)(k), for k∈K, is first multiplied with the normalized eigenvector {tilde over (v)}_(ut)(k) by a unit 460 and then further multiplied with the correction matrix {circumflex over (K)}_(ut)(k) by a unit 462 to obtain the transmit vector {tilde over (x)}_(up)(k). The vector {tilde over (x)}_(up)(k), for k ∈K, is then processed by a transmit chain 464 within modulator 154 y and transmitted over the MIMO channel to access point 110 y. Unit 460 performs spatial processing for the uplink data transmission for the beam-steering mode.

At access point 110 y, the uplink signals are processed by a receive chain 424 within demodulator 124 y to obtain the receive vector {tilde over (r)}_(up)(k), for k∈K. Within an RX spatial processor 140 y, a unit 426 performs an inner product of the receive vector {tilde over (r)}_(up)(k), for k∈K, with the matched filter vector {tilde over (m)}_(ap)(k). The inner product result is then is scaled by {tilde over (λ)}_(up) ⁻¹(k) by a unit 428 to obtain the symbol ŝ_(up)(k), which is an estimate of the modulation symbol s_(up)(k). Units 426 and 428 perform spatial processing for the uplink matched filtering for the beam-steering mode.

4. Steered Reference

As shown in equation (15), at the access point, the received uplink vector r_(up)(k), for k∈K, in the absence of noise is equal to the data vector s_(up)(k) transformed by Û_(ap)(k){circumflex over (Σ)}(k), which is the matrix Û_(ap)(k) of left eigenvectors of Ĥ_(cup)(k) scaled by the diagonal matrix {circumflex over (Σ)}(k) of singular values. As shown in equations (17) and (18), because of the reciprocal channel and the calibration, the matrix Û_(ap)*(k) and its transpose are used for spatial processing of the downlink transmission and spatial processing (matched filtering) of the received uplink transmission, respectively.

A steered reference (or steered pilot) may be transmitted by the user terminal and used by the access point to obtain estimates of both Û_(ap)(k) and {circumflex over (Σ)}(k), for k∈K, without having to estimate the MIMO channel or perform the singular value decomposition. Similarly, a steered reference may be transmitted by the access point and used by the user terminal to obtain estimates of both {circumflex over (V)}_(ut)(k) and {circumflex over (Σ)}(k).

A steered reference comprises a specific OFDM symbol (which is referred to as a pilot or “P” OFDM symbol) that is transmitted from all of the N_(ut) antennas at the user terminal (for the uplink) or the N_(ap) antennas at the access point (for the downlink). The P OFDM symbol is transmitted on only one wideband eigenmode by performing spatial processing with the set of eigenvectors for that wideband eigenmode.

A. Uplink Steered Reference

An uplink steered reference transmitted by the user terminal may be expressed as: x _(up,m)(k)={circumflex over (K)} _(ut)(k){circumflex over (v)} _(ut,m)(k)p(k), for k∈K,   Eq (31)

-   -   where x_(up,m)(k) is the transmit vector for the k-th subband of         the m-th wideband eigenmode;     -   {circumflex over (v)}_(ut,m)(k) is the eigenvector for the k-th         subband of the m-th wideband eigenmode; and     -   p(k) is a pilot modulation symbol to be transmitted on the k-th         subband. The eigenvector {circumflex over (v)}_(ut,m)(k) is the         m-th column of the matrix {circumflex over (V)}_(ut)(k), where         {circumflex over (V)}_(ut)(k)=[{circumflex over (v)}_(ut,1)(k)         {circumflex over (v)}_(ut,2)(k) . . . {circumflex over         (v)}_(ut,N) _(ut) (k)].

The received uplink steered reference at the access point may be expressed as: $\begin{matrix} \begin{matrix} {{{{\underset{\_}{r}}_{{up},m}(k)} = {{{{\underset{\_}{H}}_{up}(k)}{{\underset{\_}{x}}_{{up},m}(k)}} + {{\underset{\_}{n}}_{up}(k)}}},{{{for}\quad k} \in {K.}}} \\ {= {{{{\underset{\_}{H}}_{up}(k)}{{\hat{\underset{\_}{K}}}_{ut}(k)}{{\hat{\underset{\_}{v}}}_{{ut},m}(k)}{p(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {\approx {{{{\hat{\underset{\_}{H}}}_{cup}(k)}{{\hat{\underset{\_}{v}}}_{{ut},m}(k)}{p(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {= {{{{\hat{\underset{\_}{U}}}_{ap}(k)}{\hat{\sum\limits_{\_}}\quad{(k){{\hat{\underset{\_}{V}}}_{ut}^{H}(k)}{{\hat{\underset{\_}{v}}}_{{ut},m}(k)}{p(k)}}}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {= {{{{\hat{\underset{\_}{u}}}_{{ap},m}(k)}{\sigma_{m}(k)}{p(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \end{matrix} & {{Eq}\quad(32)} \end{matrix}$

-   -   where r_(up,m)(k) is the received vector for the uplink steered         reference for the k-th subband of the m-th wideband eigenmode;         and     -   σ_(m)(k) is the singular value for the k-th subband of the m-th         wideband eigenmode.

Techniques to estimate the channel response based on the steered reference are described in further detail below.

B. Downlink Steered Reference

A downlink steered reference transmitted by the access point may be expressed as: x _(dn,m)(k)={circumflex over (K)} _(ap)(k)û _(ap,m)*(k)p(k) , for k∈K,   Eq (33)

-   -   where x_(dn,m)(k) is the transmit vector for the k-th subband of         the m-th wideband eigenmode; and     -   û_(ap,m)(k) is the eigenvector for the k-th subband of the m-th         wideband eigenmode.

The steering vector û_(ap,m)*(k) is the m-th column of the matrix Û_(ap)*(k), where Û_(ap)*(k)=[û_(ap,1)*(k)û_(ap,2)(k) . . . û_(ap,N) _(ap) *(k)].

The downlink steered reference may be used by the user terminal for various purposes. For example, the downlink steered reference allows the user terminal to determine what kind of estimate the access point has for the MIMO channel (since the access point has an estimate of an estimate of the channel). The downlink steered reference may also be used by the user terminal to estimate the received SNR of downlink transmission.

C. Steered Reference For Beam-Steering

For the beam-steering mode, the spatial processing on the transmit side is performed using a set of normalized eigenvectors for the principal wideband eigenmode. The overall transfer function with a normalized eigenvector is different from the overall transfer function with an unnormalized eigenvector (i.e., H_(cup)(k){circumflex over (v)}_(ut,1)(k)≠H_(cup)(k){tilde over (v)}_(ut)(k)). A steered reference generated using the set of normalized eigenvectors for all subbands may then be sent by the transmitter and used by the receiver to derive the matched filter vectors for these subbands for the beam-steering mode.

For the uplink, the steered reference for the beam-steering mode may be expressed as: {tilde over (x)}up,sr(k)={circumflex over (K)} _(ut)(k){tilde over (v)} _(ut)(k)p(k), for k∈K.  Eq (34)

At the access point, the receive uplink steered reference for the beam-steering mode may be expressed as: $\begin{matrix} \begin{matrix} {{{{\overset{\sim}{\underset{\_}{r}}}_{{up},{sr}}(k)} = {{{{\underset{\_}{H}}_{up}(k)}{{\underset{\_}{x}}_{{up},{sr}}(k)}} + {{\underset{\_}{n}}_{up}(k)}}},{{{for}\quad k} \in {K.}}} \\ {= {{{{\underset{\_}{H}}_{up}(k)}{{\hat{\underset{\_}{K}}}_{ut}(k)}{{\overset{\sim}{\underset{\_}{v}}}_{ut}(k)}{p(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \\ {= {{{{\underset{\_}{H}}_{cup}(k)}{{\overset{\sim}{\underset{\_}{v}}}_{ut}(k)}{p(k)}} + {{\underset{\_}{n}}_{up}(k)}}} \end{matrix} & {{Eq}\quad(35)} \end{matrix}$

To obtain the matched filter row vector {tilde over (m)}_(ap)(k) for the uplink transmission with beam-steering, the received vector {tilde over (r)}_(up,sr)(k) for the steered reference is first multiplied with p*(k). The result is then integrated over multiple received steered reference symbols to form an estimate of H_(cup)(k){tilde over (v)}_(ut)(k). The vector {tilde over (m)}_(ap)(k) is then the conjugate transpose of this estimate.

While operating in the beam-steering mode, the user terminal may transmit multiple symbols of steered reference, for example, one or more symbols using the normalized eigenvector {tilde over (v)}_(ut)(k), one or more symbols using the eigenvector {circumflex over (v)}_(ut)(k) for the principal eigenmode, and possibly one or more symbols using the eigenvectors for the other eigenmodes. The steered reference symbols generated with {tilde over (v)}ut(k) may be used by the access point to derive the matched filter vector {tilde over (m)}_(ap)(k). The steered reference symbols generated with {circumflex over (v)}_(ut,1)(k) may be used to obtain û_(ap,1)(k), which may then be used to derive the normalized eigenvector ũ_(ap)(k) used for beam-steering on the downlink. The steered reference symbols generated with the eigenvectors {circumflex over (v)}_(ut,2)(k) through {circumflex over (v)}_(ut,N) _(s) (k) for the other eigenmodes may be used by the access point to obtain û_(ap,2)(k) through û_(ap,N) _(s) (k) and the singular values for these other eigenmodes. This information may then be used by the access point to determine whether to use the spatial multiplexing mode or the beam-steering mode for data transmission.

For the downlink, the user terminal may derive the matched filter vector {tilde over (m)}_(ut)(k) for the beam-steering mode based on the calibrated downlink channel response estimate Ĥ_(cdn)(k). In particular, the user terminal has û_(ap,1)(k) from the singular value decomposition of Ĥ_(cdn)(k) and can derive the normalized eigenvector ũ_(ap)(k). The user terminal can then multiply ũ_(ap)(k) with Ĥ_(cdn)(k) to obtain Ĥ_(cdn)(k)ũ_(ap)(k), and may then derive {tilde over (m)}_(ut)(k) based on Ĥ_(cdn)(k)ũ_(ap)(k). Alternatively, a steered reference may be sent by the access point using the normalized eigenvector ũ_(ap)(k), and this steered reference may be processed by the user terminal in the manner described above to obtain {tilde over (m)}_(ut)(k).

D. Channel Estimation Based on Steered Reference

As shown in equation (32), at the access point, the received uplink steered reference (in the absence of noise) is approximately û_(ap,m)(k)σ_(m)(k)p(k). The access point can thus obtain an estimate of the uplink channel response based on the steered reference sent by the user terminal. Various estimation techniques may be used to obtain the channel response estimate.

In one embodiment, to obtain an estimate of û_(ap,m)(k), the received vector r_(up,m)(k) for the steered reference for the m-th wideband eigenmode is first multiplied with the complex conjugate of the pilot modulation symbol, p *(k), used for the steered reference. The result is then integrated over multiple received steered reference symbols for each wideband eigenmode to obtain an estimate of ûap,m(k)σ_(m)(k), which is a scaled left eigenvector of Ĥ_(cup)(k) for the m-th wideband eigenmode. Each of the N_(ap) entries of û_(ap,m)(k) is obtained based on a corresponding one of the N_(ap) entries for r_(up,m)(k), where the N_(ap) entries of r_(up,m)(k) are the received symbols obtained from the N_(ap) antennas at the access point. Since eigenvectors have unit power, the singular value σ_(m)(k) may be estimated based on the received power of the steered reference, which can be measured for each subband of each wideband eigenmode.

In another embodiment, a minimum mean square error (MMSE) technique is used to obtain an estimate of û_(ap,m)(k) based on the received vector r_(up,m)(k) for the steered reference. Since the pilot modulation symbols p(k) are known, the access point can derive the estimate of û_(ap,m)(k) such that the mean square error between the received pilot symbols (obtained after performing the matched filtering on the received vector r_(up,m)(k)) and the transmitted pilot symbols is minimized. The use of the MMSE technique for spatial processing at the receiver is described in detail in commonly assigned U.S. patent application Ser. No. 09/993,087, entitled “Multiple-Access Multiple-Input Multiple-Output (MIMO) Communication System,” filed Nov. 6, 2001.

The steered reference is sent for one wideband eigenmode in any given symbol period, and may in turn be used to obtain an estimate of one eigenvector for each subband of that wideband eigenmode. Thus, the receiver is able to obtain an estimate of one eigenvector in a unitary matrix for any given symbol period. Since estimates of multiple eigenvectors for the unitary matrix are obtained over different symbol periods, and due to noise and other sources of degradation in the transmission path, the estimated eigenvectors for the unitary matrix are not likely be orthogonal. If the estimated eigenvectors are thereafter used for spatial processing of data transmission on the other link, then any errors in orthogonality in these estimated eigenvectors would result in cross-talk among the eigenmodes, which may degrade performance.

In an embodiment, the estimated eigenvectors for each unitary matrix are forced to be orthogonal to each other. The orthogonalization of the eigenvectors may be achieved using the Gram-Schmidt technique, which is described in detail in the aforementioned reference from Gilbert Strang, or some other technique.

Other techniques to estimate the channel response based on the steered reference may also be used, and this is within the scope of the invention.

The access point can thus estimate both Û_(ap)(k) and {circumflex over (Σ)}(k) based on the steered reference sent by the user terminal, without having to estimate the uplink channel response or perform singular value decomposition on Ĥ_(cup)(k). Since only N_(ut)wideband eigenmodes have any power, the matrix Û_(ap)(k) of left eigenvectors of Ĥ_(cup)(k) is effectively (N_(ap)×N_(ut)), and the matrix {circumflex over (Σ)}(k) may be considered to be (N_(ut)×N_(ut)).

The processing at the user terminal to estimate the matrices {circumflex over (V)}_(ut)(k) and {circumflex over (Σ)}(k), for k∈K, based on the downlink steered reference may be performed similar to that described above for the uplink steered reference.

5. Channel Estimation and Spatial Processing

FIG. 5 is a flow diagram of a specific embodiment of a process 500 for performing channel estimation and spatial processing at the access point and user terminal, in accordance with one embodiment of the invention. Process 500 includes two parts—calibration (block 510) and normal operation (block 520).

Initially, the access point and user terminal perform calibration to determine the differences in the responses of their transmit and receive chains and to obtain correction matrices {circumflex over (K)}_(ap)(k) and {circumflex over (K)}_(ut)(k), for k∈K (at block 512). The calibration only needs to be performed once (e.g., at the start of a communication session, or the very first time the user terminal is powered up). The correction matrices {circumflex over (K)}_(ap)(k) and {circumflex over (K)}_(ut)(k) are thereafter used by the access point and user terminal, respectively, on the transmit side as described above.

During normal operation, the access point transmits a MIMO pilot on the calibrated downlink channel (at block 522). The user terminal receives and processes the MIMO pilot, estimates the calibrated downlink channel response based on the received MIMO pilot, and maintains an estimate of the calibrated downlink channel response (at block 524). It can be shown that performance is better (i.e., less degradation) when the channel response estimate is accurate. An accurate channel response estimate may be obtained by averaging the estimates derived from multiple received MIMO pilot transmissions.

The user terminal then decomposes the calibrated downlink channel response estimate, Ĥ_(cdn)(k), for k∈K, to obtain the diagonal matrix {circumflex over (Σ)}(k) and the unitary matrix {circumflex over (V)}_(ut)*(k) (at block 526). The matrix {circumflex over (V)}_(ut)*(k) contains the left eigenvectors of Ĥ_(cdn)(k) and {circumflex over (V)}_(ut)(k) contains the right eigenvectors of Ĥ_(cup)(k). The matrix {circumflex over (V)}_(ut)(k) can thus be used by the user terminal to perform spatial processing for data transmission received on the downlink as well as for data transmission to be sent on the uplink.

The user terminal then transmits a steered reference on the uplink to the access point using the eigenvectors in the matrix {circumflex over (V)}_(ut)(k), as shown in equation (31) (at block 530). The access point receives and processes the uplink steered reference to obtain the diagonal matrix {circumflex over (Σ)}(k) and the unitary matrix Û_(ap)(k), for k∈K (at block 532). The matrix Û_(ap)(k) contains the left eigenvectors of Ĥ_(cup)(k) and Û_(ap)(k) contains the right eigenvectors of Ĥ_(cdn)(k). The matrix Û_(ap)(k) can thus be used by the access point to perform spatial processing for data transmission received on the uplink as well as for data transmission to be sent on the downlink.

The matrix Û_(ap)(k), for k∈K, is obtained based on an estimate of the uplink steered reference, which in turn is generated with the eigenvector that is obtained based on an estimate of the calibrated downlink channel response. Thus, the matrix Û_(ap)(k) is effectively an estimate of an estimate. The access point may average the uplink steered reference transmissions to obtain more accurate estimate of the actual matrix U_(ap)(k).

Once the user terminal and access point obtain the matrices {circumflex over (V)}_(ut)(k) and Ûap(k), respectively, data transmission can commence on the downlink and/or uplink. For downlink data transmission, the access point performs spatial processing on symbols with the matrix Û_(ap)*(k) of right eigenvectors of Ĥ_(cdn)(k) and transmits to the user terminal (at block 540). The user terminal would then receive and spatially process the downlink data transmission with the matrix {circumflex over (V)}_(ut) ^(T)(k), which is the conjugate transpose of the matrix {circumflex over (V)}_(ut)*(k) of left eigenvectors of Ĥ_(cdn)(k) (at block 542). For uplink data transmission, the user terminal performs spatial processing on symbols with the matrix {circumflex over (V)}_(ut)(k) of right eigenvectors of Ĥ_(cup)(k), and transmits to the access point (at block 550). The access point would then receive and spatially process the uplink data transmission with the matrix Û_(ap)(k), which is the conjugate transpose of the matrix Û_(ap)(k) of left eigenvectors of Ĥ_(cup)(k) (at block 552).

The downlink and/or uplink data transmission can continue until terminated by either the access point or user terminal. While the user terminal is idle (i.e., with no data to transmit or receive), the MIMO pilot and/or steered reference may still be sent to allow the access point and user terminal to maintain up-to-date estimates of the downlink and uplink channel responses, respectively. This would then allow data transmission to commence quickly, if and when resumed.

For clarity, the channel estimation and spatial processing techniques have been described for a specific embodiment in which the user terminal estimates the calibrated downlink channel response based on a downlink MIMO pilot and performs the singular value decomposition. The channel estimation and singular value decomposition may also be performed by the access point, and this is within the scope of the invention. In general, because of the reciprocal channel for a TDD system, the channel estimation needs only be performed at one end of the link.

The techniques described herein may be used with or without calibration. Calibration may be performed to improve the channel estimates, which may then improve system performance.

The techniques described herein may also be used in conjunction with other spatial processing techniques, such as water-filling for transmit power allocation among the wideband eigenmodes and channel inversion for transmit power allocation among the subbands of each wideband eigenmode. Channel inversion and water-filling are described in the aforementioned U.S. Patent Application Ser. No. 60/421,309.

The channel estimation and spatial processing techniques described herein may be implemented by various means. For example, these techniques may be implemented in hardware, software, or a combination thereof. For a hardware implementation, the elements used to implement the techniques described herein may be implemented within one or more application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), processors, controllers, micro-controllers, microprocessors, other electronic units designed to perform the functions described herein, or a combination thereof.

For a software implementation, the channel estimation and spatial processing techniques may be implemented with modules (e.g., procedures, functions, and so on) that perform the functions described herein. The software codes may be stored in a memory unit (e.g., memory units 132 and 182 in FIG. 1) and executed by a processor (e.g., controllers 130 and 180). The memory unit may be implemented within the processor or external to the processor, in which case it can be communicatively coupled to the processor via various means as is known in the art.

Headings are included herein for reference and to aid in locating certain sections. These headings are not intended to limit the scope of the concepts described therein under, and these concepts may have applicability in other sections throughout the entire specification.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein. 

1. A method of performing spatial processing in a wireless time division duplexed (TDD) multiple-input multiple-output (MIMO) communication system, comprising: processing a MIMO pilot received via a first link to obtain a plurality of eigenvectors usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link, wherein the MIMO pilot comprises a plurality of pilot transmissions sent from a plurality of transmit antennas, and wherein the pilot transmission from each transmit antenna is identifiable by a receiver of the MIMO pilot; performing spatial processing on a first data transmission received via the first link with the plurality of eigenvectors to recover data symbols for the first data transmission; and performing spatial processing for a second data transmission with the plurality of eigenvectors prior to transmission over the second link.
 2. The method of claim 1, further comprising: performing spatial processing on pilot symbols with at least one of the eigenvectors to generate a steered pilot for transmission on at least one eigenmode of a MIMO channel for the second link.
 3. The method of claim 1, further comprising: performing calibration to obtain correction factors; and scaling the second data transmission with the correction factors prior to transmission over the second link.
 4. The method of claim 1, wherein the TDD MIMO communication system utilizes orthogonal frequency division multiplexing (OFDM), and wherein the spatial processing is performed for each of a plurality of subbands.
 5. An apparatus in a wireless time division duplexed (TDD) multiple-input multiple-output (MIMO) communication system, comprising: means for processing a MIMO pilot received via a first link to obtain a plurality of eigenvectors usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link, wherein the MIMO pilot comprises a plurality of pilot transmissions sent from a plurality of transmit antennas, and wherein the pilot transmission from each transmit antenna is identifiable by a receiver of the MIMO pilot; means for performing spatial processing on a first data transmission received via the first link with the plurality of eigenvectors to recover data symbols for the first data transmission; and means for performing spatial processing for a second data transmission with the plurality of eigenvectors prior to transmission over the second link.
 6. The apparatus of claim 5, further comprising: means for performing spatial processing on pilot symbols with at least one of the eigenvectors to generate a steered pilot for transmission on at least one eigenmode of a MIMO channel for the second link.
 7. The apparatus of claim 5, further comprising: means for performing calibration to obtain correction factors; and means for scaling the second data transmission with the correction factors prior to transmission over the second link.
 8. An apparatus in a wireless time division duplexed (TDD) multiple-input multiple-output (MIMO) communication system, comprising: a controller operative to process a MIMO pilot received via a first link to obtain a plurality of eigenvectors usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link, wherein the MIMO pilot comprises a plurality of pilot transmissions sent from a plurality of transmit antennas, and wherein the pilot transmission from each transmit antenna is identifiable by a receiver of the MIMO pilot; a receive spatial processing operative to perform spatial processing on a first data transmission received via the first link with the plurality of eigenvectors to recover data symbols for the first data transmission; and a transmit spatial processor operative to perform spatial processing for a second data transmission with the plurality of eigenvectors prior to transmission over the second link
 9. The apparatus of claim 8, wherein the transmit spatial processor is further operative to perform spatial processing on pilot symbols with at least one of the eigenvectors to generate a steered pilot for transmission on at least one eigenmode of a MIMO channel for the second link.
 10. The apparatus of claim 8, wherein the controller is further operative to perform calibration to obtain correction factors, and wherein the transmit spatial processor is further operative to scale the second data transmission with the correction factors prior to transmission over the second link.
 11. A method of performing spatial processing in a wireless time division duplexed (TDD) multiple-input multiple-output (MIMO) communication system, comprising: processing a steered pilot received via at least one eigenmode of a MIMO channel for a first link to obtain at least one eigenvector usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link; performing spatial processing on a first data transmission received via the first link with the at least one eigenvector; and performing spatial processing for a second data transmission with the at least one eigenvector prior to transmission over the second link.
 12. The method of claim 11, further comprising: generating a MIMO pilot for transmission over the second link, wherein the MIMO pilot comprises a plurality of pilot transmissions sent from a plurality of transmit antennas, and wherein the pilot transmission from each transmit antenna is identifiable by a receiver of the MIMO pilot.
 13. An apparatus in a wireless time division duplexed (TDD) multiple-input multiple-output (MIMO) communication system, comprising: means for processing a steered pilot received via at least one eigenmode of a MIMO channel for a first link to obtain at least one eigenvector usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link; means for performing spatial processing on a first data transmission received via the first link with the at least one eigenvector; and means for performing spatial processing for a second data transmission with the at least one eigenvector prior to transmission over the second link.
 14. The apparatus of claim 13, further comprising: means for generating a MIMO pilot for transmission over the second link, wherein the MIMO pilot comprises a plurality of pilot transmissions sent from a plurality of transmit antennas, and wherein the pilot transmission from each transmit antenna is identifiable by a receiver of the MIMO pilot.
 15. An apparatus in a wireless time division duplexed (TDD) multiple-input multiple-output (MIMO) communication system, comprising: a controller operative to process a steered pilot received via at least one eigenmode of a MIMO channel for a first link to obtain at least one eigenvector usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link; a receive spatial processor operative to perform spatial processing on a first data transmission received via the first link with the at least one eigenvector; and a transmit spatial processor operative to perform spatial processing for a second data transmission with the at least one eigenvector prior to transmission over the second link.
 16. The apparatus of claim 15, wherein the transmit spatial processor is further operative to generate a MIMO pilot for transmission over the second link, wherein the MIMO pilot comprises a plurality of pilot transmissions sent from a plurality of transmit antennas, and wherein the pilot transmission from each transmit antenna is identifiable by a receiver of the MIMO pilot.
 17. A method of performing spatial processing in a wireless time division duplexed (TDD) multiple-input multiple-output (MIMO) orthogonal frequency division multiplexing (OFDM) communication system, comprising: processing a first transmission received via a first link to obtain a matrix of eigenvectors for each of a plurality of subbands, wherein a plurality of matrices of eigenvectors are obtained for the plurality of subbands and are usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link; and performing spatial processing for a second transmission with the plurality of matrices of eigenvectors prior to transmission over the second link.
 18. The method of claim 17, further comprising: ordering the eigenvectors in each matrix based on channel gains associated with the eigenvectors.
 19. The method of claim 18, wherein the second transmission is sent on at least one wideband eigenmode, each wideband eigenmode associated with a set of eigenvectors in the plurality of matrices having same order after the ordering.
 20. A method of estimating a wireless channel in a time division duplexed (TDD) multiple-input multiple-output (MIMO) communication system, comprising: processing a pilot transmission received via a first link to obtain a channel response estimate for the first link; and decomposing the channel response estimate to obtain a matrix of eigenvectors usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link.
 21. A method of estimating a wireless channel in a time division duplexed (TDD) multiple-input multiple-output (MIMO) communication system, comprising: receiving a steered pilot on at least one eigenmode of a MIMO channel for a first link; and processing the received steered pilot to obtain at least one eigenvector usable for spatial processing for both data transmission received via the first link and data transmission sent via a second link.
 22. The method of claim 21, wherein the processing includes demodulating the received steered pilot to remove modulation due to pilot symbols used to generate the steered pilot, and processing the demodulated steered pilot to obtain the at least one eigenvector.
 23. The method of claim 21, wherein the at least one eigenvector is obtained based on a minimum mean square error (MMSE) technique.
 24. The method of claim 21, wherein a plurality of eigenvectors are obtained and are forced to be orthogonal to one another.
 25. A method for performing data processing in a wireless communication system including an access point and a user terminal, the method comprising: calibrating one or more communication links including a first link and a second link between the access point and the user terminal to form a calibrated first link and a calibrated second link; obtaining a channel response estimate for the calibrated first link based on one or more pilots transmitted on the calibrated first link; and decomposing the channel response estimate to obtain one or more eigenvectors usable for spatial processing of the one or more communication links.
 26. The method of claim 25 wherein calibrating comprises: determining one or more sets of correction factors based on estimates of channel responses for the one or more communication links; and applying the one or more sets of correction factors to the first and second links to form the calibrated first and second links.
 27. The method of claim 25 further comprising: performing spatial processing for data transmissions on the first and second links using the one or more eigenvectors obtained from decomposing the channel response estimate for the calibrated first link.
 28. The method of claim 27 wherein performing spatial processing comprises: transmitting a steered reference on the second link using the one or more eigenvectors.
 29. The method of claim 28 further comprising: performing spatial processing on or more pilot symbols with the one or more eigenvectors to generate the steered reference.
 30. An apparatus for performing data processing in a wireless communication system including an access point and a user terminal, the apparatus comprising: means for calibrating one or more communication links including a first link and a second link between the access point and the user terminal to form a calibrated first link and a calibrated second link; means for obtaining a channel response estimate for the calibrated first link based on one or more pilots transmitted on the calibrated first link; and means for decomposing the channel response estimate to obtain one or more eigenvectors usable for spatial processing of the one or more communication links.
 31. The apparatus of claim 30 wherein calibrating comprises: means for determining one or more sets of correction factors based on estimates of channel responses for the one or more communication links; and means for applying the one or more sets of correction factors to the first and second links to form the calibrated first and second links.
 32. The apparatus of claim 30 further comprising: performing spatial processing for data transmissions on the first and second links using the one or more eigenvectors obtained from decomposing the channel response estimate for the calibrated first link.
 33. The apparatus of claim 32 wherein performing spatial processing comprises: transmitting a steered reference on the second link using the one or more eigenvectors.
 34. The apparatus of claim 33 further comprising: performing spatial processing on or more pilot symbols with the one or more eigenvectors to generate the steered reference. 